Active bacteria driving N2O mitigation and dissimilatory nitrate reduction to ammonium in ammonia recovery bioreactors

Abstract

Shifting from ammonia removal to recovery is the current strategy in wastewater treatment management. We recently developed a microaerophilic activated sludge system for retaining ammonia whereas removing organic carbon with minimal N2O emissions. A comprehensive understanding of nitrogen metabolisms in the system is essential to optimize system performance. Here, we employed metagenomics and metatranscriptomics analyses to characterize the microbial community structure and activity during the transition from a microoxic to an oxic condition. A hybrid approach combining high-quality short reads and Nanopore long reads reconstructed 98 medium- to high-quality non-redundant metagenome-assembled genomes from the communities. The suppressed bacterial ammonia monooxygenase (amoA) expression was upregulated after shifting from a microoxic to an oxic condition. Seventy-three reconstructed metagenome-assembled genomes (>74% of the total) from 11 bacterial phyla harbored genes encoding proteins involved in nitrate respiration; 39 (~53%) carried N2O reductase (nosZ) genes with the predominance of clade II nosZ (31 metagenome-assembled genomes), and 24 (~33%) possessed nitrite reductase (ammonia-forming) genes (nrfA). Clade II nosZ and nrfA genes exhibited the highest and second-highest expressions among nitrogen metabolism genes, indicating robust N2O consumption and ammonification. Non-denitrifying clade II nosZ bacteria, Cloacibacterium spp., in the most abundant and active phylum Bacteroioda, were likely major N2O sinks. Elevated dissolved oxygen concentration inhibited clade II nosZ expression but not nrfA expression, potentially switching phenotypes from N2O reduction to ammonification. Collectively, the multi-omics analysis illuminated bacteria responsible for N2O reduction and ammonification in microoxic and oxic conditions, facilitating high-performance ammonia recovery.